ES2211688T3 - HEAT TRANSPORTATION SYSTEM WITH HEAT PRODUCTION INSTALLATION WITH VOLUMETRIC CURRENT CONTROL. - Google Patents

Abstract

The heat transfer circuit (10) has a pipe system for a fluid heating medium with a pump (12). A secondary flow circuit (17) is connected to the pipe system with a secondary radiator and a secondary pump. This is connectable to the main circuit by a valve. A section of the secondary circuit is integrated with the main circuit.

Description

Heat transport system with installation of Heat production with volumetric current control.

The invention relates to a system of heat transport with a production circuit and a circuit of consumption, which are linked through a decoupling element, said production circuit comprising a device of heat production, which transmits heat to the fluid, a first pipe system that fills with fluid as well as a pump to circulate the fluid found in the first system of pipes, and said consumption circuit comprising at least one heat emitting device that receives the fluid, another system of pipes, as well as a pump to circulate the fluid which is in the other pipe system.

In the state of the art systems are used of heat transport of the type mentioned to adapt the heat produced in a heat production device, with the help of decoupling element, flexibly to heat absorption, subject to temporary oscillations of at least one device heat emission The production circuit pump by a on the other hand, as well as the consumption circuit on the other hand, are provided to ensure a fluid carrying capacity appropriate for the magnitude of the corresponding circuit. Particularly, in the event that it is provided in the circuit of I consume a multitude of supply devices connected in parallel, however, it has been shown that performance or profitability of conventional heat transport systems does not correspond to the desired requirements, because in The functional development of regulation of a multitude of heat production devices by a production circuit and, consequently, the performance calorific provided in the production circuit does not move from effective way to the consumption circuit.

From EP 0 445 310 it is also known a device of the type mentioned. This device contains a input temperature regulation device in a heating system with a multiple boiler arrangement with several boilers connected in parallel, where (in the circuit primary) a boiler temperature sensor is provided for boiler temperature collection, a valve in the pipeline inlet or in the boiler outlet pipe, as well as a circulation pump, respectively, and where a decoupling element connected hydraulically between the installation of several boilers and the heat consumer, as well as at least one electronic regulation device, which captures the output signals of the boiler temperature sensor (in the  primary circuit) corresponding to the boiler temperature and controls, based on a reference variable of the input temperature corresponding to a theoretical value as well as, under certain operating conditions, based on a real value of the input temperature corresponding to the inlet temperature in the primary circuit of the installation of multiple boilers in front of the hydraulic decoupling element, the boiler heating temperature, and where appropriate corresponding adjustment bodies and / or pumps, and, of the same way, connect, disconnect, depending on the need for heat registered by the boiler heat consumers, and controls the valves and circulation pumps, so that, to ensure a correct temperature in the secondary circuit, calculates at same time the inlet temperature, in the primary circuit front of the hydraulic decoupling element, of the boilers that are in service, also connected to an open valve according to a predetermined relationship, and the calculated value is used as actual value of the inlet temperature. The technical teaching of This prior art therefore goes through a control of the input temperature in the secondary circuit of the device  heating by boiler temperature measurements of the primary circuit of the heating device, and a calculation of the input temperature in the primary circuit of the heating device

Through the publications "Delpeche P: 'Bouteilles casse-pression et de melange, conception et comportement 'CFP Chaud froid plomberie, editions Parisians Paris, FR, Nr. 596, 1. November 1997 (1997-11-01) pages 119-124, XP000724699 ISSN: 0750-1552 "have come to our knowledge devices and procedures, in which the flow of a fluid in the pipe system with a production circuit and a Consumption circuit in many different ways.

A function of the invention is to create a system of heat transport, whose performance and profitability are seen enhanced by the creation of a device regulation heat production (multiple boiler installation) with a effective operation against heat transport systems known.

According to the invention, this problem is solved. because in the consumption circuit a sensor device is provided that measures the flow rate of the fluid in this pipe system, and it is expected a control device that controls pump activity provided in the production circuit according to the magnitudes determined by the sensor device. The principle of invention can also, therefore, be transmitted without variation to refrigerating devices

Preferred embodiments of the The invention is the subject of the secondary claims.

In the heat transport system according to the invention, thanks to the characteristic that in the circuit of consumption is provided a sensor device, which measures the flow of fluid present in this pipe system, and a control device, which controls pump activity provided in the production circuit according to the magnitudes determined by the sensor device, the amount of fluid flow in the production circuit can be regulated according to the fluid flow rate in the consumption circuit, so that can compensate for a high volumetric current in the heat emission devices of the consumption circuit by an increase in fluid flow in the production circuit. By this is possible for the first time, thanks to the system according to the invention, securely guarantee a practicable regulation and effective of several heat production devices of a production circuit, and also limit the number of devices of heat production necessary for operation in comparison with heat transport systems conventional.

According to a first preferred embodiment of the heat transport system according to the invention, it is provided that, in addition to said sensor device in the consumption circuit, a sensor device is provided in the production circuit and that the pump activity planned in the production circuit can be controlled in relation to the data provided by the sensor devices, such that the volumetric current of the production circuit is proportional to the current volumetric consumption circuit by default. Too It is particularly advantageous, that in addition to the sensor device from the consumption circuit a sensor device is provided in the production circuit, and that the activity of the pump or of the pumps provided in the production circuit are controlled in relation to the data provided by the sensor device, of such that the value of the volumetric current in the circuit of production corresponds to the value of the current volumetric in the consumption circuit.

According to another preferred embodiment of the heat transport system according to the invention, it is envisioned that the production circuit sensor device be arranged in the input current on the production side in the direction of the flow before the hydraulic decoupling element, and that the sensor device of the consumption circuit is provided in the input current on the consumer side after the item Hydraulic decoupling. Alternatively, it can be provided time also the arrangement of the circuit sensor device of production in the return current on the production side in the direction of the flow after the decoupling element hydraulic, and the consumption circuit sensor device in the return current on the consumer side before the element of hydraulic decoupling Also, the sensor devices particularly they can also be designed as sensors temperature, since the measurement data of the devices of the sensors, the same value of volumetric currents in the production circuit and in the consumption circuit A device can be provided regulation, accordingly, so that, being identical the measurement data of the sensor devices, a same value of the volumetric currents in the circuit production and in the circuit of consumption.

According to an important embodiment preferred heat transport system according to the invention. it is expected that instead of a production device of heat various heat production devices are provided in the production circuit, and that the pump is sized and conceived in such a way that it is capable of transporting in the flow of the volumetric current of the production circuit, by just a heat producing device, a current volumetric with the same flow rate as the consumption circuit. From In this way, optimal system service is guaranteed according to the invention.

According to another important embodiment preferred heat transport system according to the invention, it is envisioned that instead of a production device of heat various heat production devices are provided in the production circuit, and that the pump is designed and sized in such a way that it is capable of transporting in the volumetric flow of the production circuit, by only a heat producing device, a current volumetric calculated according to a fraction of the current value volumetric consumption circuit. This way you can set different input temperatures in the circuit production and in the circuit of consumption.

According to an alternative embodiment of the system according to the invention, it can also be provided that instead of a heat producing device are provided several heat production devices in the production circuit, and the pump is designed and sized in such a way that it is capable of transporting in the flow of the volumetric current of the circuit of production, by means of only one production device of heat, a volumetric current calculated according to a multiple of the value of the volumetric current of the consumption circuit. This way the small non-optimal variations of the current Volumetric can be compensated.

According to another preferred embodiment of the heat transport system according to the invention is provided, that All circuit heat production devices Production are driven by a common adjustable pump. Alternatively, it can also be provided, however, that at each one of the heat production devices of the circuit production is assigned an independent adjustable pump. From this way guarantees an adjustable, precise and flexible control, of the volumetric current of each production device of individual heat

According to another preferred embodiment of the heat transport system according to the invention is provided, that the data signals measured by the measuring device of the volumetric current controls a regulating device that regulates the volumetric current that passes through the device heat production The regulating device may be also configured as a regulating valve, by example.

According to another preferred embodiment of the heat transport system according to the invention, is provided, that the volumetric current measuring device is configured as a differential pressure measurement sensor, which measures a pressure difference between the inlet and outlet of A heat production device.

According to a preferred embodiment important in practice, of the heat transport system according to the invention, it is provided that the decoupling element is configured as a hydraulic decoupling device, formed by a hollow body, which comprises at least one entrance and at least an outlet to the production circuit's piping system, and at least one entrance and at least one exit to the system of consumer circuit pipes. This guarantees a simple way the necessary coupling between the fluid in the Production circuit and consumption circuit.

According to another preferred embodiment of the heat transport system according to the invention, is provided that the sensor device is near the element of decouple Therefore, the sensor device is provided preferably at the output of the consumption circuit of the element of decouple and also can also be integrated in the output of the consumption circuit of the decoupling element. In this way it can be achieved in a very simple and efficient way a procedure for measuring fluid flow in the circuit consumption.

According to another preferred embodiment of the heat transport system according to the invention, is provided that the decoupling element has a second system of pipes, which forms a secondary current circuit in direction to the primary current circuit, so that a section of the secondary current circuit is integrated into the primary current circuit With this measure, the  performance and profitability compared to transport systems known heat. This embodiment offers a alternative for the case in which the decoupling element is integrated into a second pipe system, which forms at least one secondary current circuit in the direction of a circuit primary current, so that in the decoupling element a section of the secondary current circuit is integrated into the primary current circuit

The transport system sensor device of heat according to the invention is preferably configured as an electronic sensor device, which emits electrical signals in form of quantities in the control device. The devices electronic sensors also have the advantage that they can be manufactured very small, with very small dimensions, and therefore both provide the fluid with little resistance, and on the other side, because of this, they provide great precision in the measurement.

In the heat transport system according to the invention, the activity of the pump provided in the circuit of production can preferably be regulated continuously, to continuously lower or increase the pumping force. Alternatively, the intended pump could be activated or deactivated. for a period of time in the production circuit.

According to another preferred embodiment of the heat transport system according to the invention, is provided that the pumping force of the pump provided in the circuit of production is established not in relation to the generator but in relation to the volumetric current of the consumption circuit.

It can also be expected, in particular, that the pumping power of the pump provided in the circuit production is established in such a way that it is able to create in the production circuit a volumetric current that corresponds approximately with the volumetric current flowing in the consumption circuit

Alternatively, it can also be provided that the pump is designed in such a way that it is able to create in the production circuit a volumetric current, calculated at 105% of the volumetric current circulating in the circuit of consumption.

In turn, alternatively, it can be expected that the pump pumping force provided in the production circuit is designed in such a way that it is able to create in the circuit of production a volumetric current, calculated at 110% of the volumetric current circulating in the consumption circuit.

Alternatively, it can also be provided that the pump pumping force provided in the production circuit is designed in such a way that it is able to create in the circuit of production a volumetric current, calculated at 115% of the volumetric current circulating in the consumption circuit, or that the pumping force of the pump provided in the circuit of production is designed in such a way that it is able to create in the production circuit a volumetric current, calculated at 120% of the volumetric current circulating in the circuit of consumption.

Alternatively, it can also be provided that the pump pumping capacity provided in the circuit production is designed in such a way that it is able to create in the production circuit a volumetric current, calculated at 90% of the volumetric current circulating in the consumption circuit, or calculated at 95% of the volumetric current flowing in The consumption circuit.

In the heat transport system according to the invention, the heat production device, which transmits heat to the fluid, can preferably be realized in the form of a heat exchanger As a heat exchanger, consider in this case particularly a heat exchanger of plates. Alternatively, it can also be provided as heat exchanger, for example, a heat exchanger of tubular beam, a collective heat exchanger or a flue gas heat exchanger.

The heat transport system according to the invention will be described below according to a form of preferred embodiment, which is represented in the figure of Drawing, where it is shown:

Fig. 1 a schematic structure of a form of preferred embodiment of the heat transport system according to the invention.

The heat transport system 10 according to the invention depicted in figure 1 comprises a circuit of production 11 and a consumption circuit 12, which are linked by a decoupling element 13, the production circuit 11 comprising three heat production devices 14, 14 'and 14 '', which transmit heat to a fluid that circulates in a system of overlapping pipes, which is composed of a first system of pipes 16 of the production circuit 11 and a second system of pipes 19 of the consumption circuit 12. The production circuit 11 includes a first pipe system 16, which is filled with the fluid, equipped with pumps 17, 17 'and 17' 'to put into circulation the fluid found in the first pipe system 16, of such that to each heat producing device 14, 14 ', 14 '' is assigned a corresponding pump 17, 17 ', 17' '. To each heat production device 14, 14 ', 14' 'is assigned, respectively, an individual device for measuring the volumetric current 24, 24 ', 24' 'so that the signals of the data determined by the measuring device of the volumetric current 24, 24 ', 24' 'respectively controls a regulating device 34, 34 ', 34' 'to regulate the current volumetric passing through each heat production device 14, 14 ', 14' '.

The consumption circuit 12 comprises two 18,18 'heat emitting devices that receive the fluid from the production circuit 11, a piping system 19 and a pump 20 to circulate the fluid in the system of pipes 19. In consumption circuit 12, a sensor device 21 fundamental to the invention, which measures the  fluid flow within a pipe section of said system of pipes 19, a control device not provided represented that controls the activity of the planned pumps 17 in the production circuit 17, 17 ', 17' 'according to the magnitudes determined by the sensor device 21, such that a high heat consumption in heat emitting devices 18, 18 'of the consumption circuit 12 can be compensated with an increase of the fluid flow in the production circuit 11. In addition to the sensor device 21 arranged in the consumption circuit 12, is provided in the production circuit 11 a sensor device 21 ' similar, whereby the activity of the pumps provided in the Production circuit 17, 17 ', 17' 'is controlled according to the data provided by the sensor device 21, 21 'in such a way, that the value of the volumetric current in the production circuit 11 corresponds to the value of the volumetric current in the consumption circuit 12. In the embodiment shown, the flow direction of the fluid in the production circuit 11 as well as in the consumption circuit 12.

In the heat transport system represented according to the invention, a decoupling element 13 is provided configured as a hydraulic decoupling element, which is formed by a hollow body full of fluid 15, and comprising a inlet 26 and outlet 27 towards the piping system 16 of the production circuit 11 and an input 28 and an output 29 towards the piping system 19 of the consumption circuit 12. The device sensor 21 is provided near the decoupling element 13. The sensor device 21 is further configured as a device electronic sensor, which emits electrical signals as magnitudes of measurement to control device not shown, operated electrically The activity of the pumps 17,17 ', 17' 'planned in the production circuit 11, it can be regulated continuously through the control device, reducing or increasing continuously pumping force of pumps 17, 17 ', 17' ', to compensate for the reduction or increase in heat consumption in heat emission devices 18, 18 'of the consumption circuit 12 reducing or increasing the flow of fluid in the circuit of production 11.

The embodiment of the invention that is just explained serves only for a better understanding of the theory of the invention established through the claims, which are not limited as such by the example of this embodiment.

Claims (34)

1. Heat transport system (10) comprising a production circuit (11) and a consumption circuit (12) that are connected by a decoupling element (13), the production circuit (11) comprising a device for heat production (14, 14 ', 14''), which transmits heat to a fluid, a first pipe system (16) filled with the fluid, and a pump (17,17', 17 ') that circulates the fluid present in the first pipe system (16), and the consumption circuit (12) comprising at least one heat emitting device (18, 18 ') receiving the fluid, another pipe system (19) and a pump (20) that circulates the fluid present in the other piping system (19), characterized by the fact that a sensor device (21) is provided in the consumption circuit (12), which detects the flow rate of fluid circulating in this pipe system (19), and because a regulating device that regulates the activity of the pump is provided ba (17) provided in the production circuit (11) according to the values determined by the sensor device (21). 2. Device according to claim 1, characterized in that in addition to the sensor device (21) provided in the consumption circuit (12), another sensor device (21 ') is provided in the production circuit (11), and The activity of the pump (17, 17 ', 17'') provided in the production circuit (11) can be regulated according to the data provided by the sensor devices (21), so that the volumetric current of the production circuit ( 11) is in a predetermined proportion with respect to the volumetric current of the consumption circuit (12). 3. Device according to claim 2, characterized in that in addition to the sensor device (21) provided in the consumption circuit (12), a sensor device (21 ') is provided in the production circuit (11), and The activity of the pump or pumps (17, 17 ', 17'') provided in the production circuit (11) is regulated according to the data provided by the sensor devices (21), so that the volumetric current value of the Production circuit (11) corresponds to the value of the volumetric current of the consumption circuit (12). Device according to any of claims 2 or 3, characterized in that the sensor device (21 ') of the production circuit (11) is arranged in the input current in the production part in the direction of the current before the hydraulic decoupling element (13), and the sensor device (21) of the consumption circuit (12) is provided in the input current on the consumer side after the hydraulic decoupling element (13). 5. Device according to any of claims 2 or 3, characterized in that the sensor device (21 ') of the production circuit (11) is arranged in the output current in the production part in the direction of the current after the hydraulic decoupling element (13), and the sensor device (21) of the consumption circuit (12) is arranged in the output current in the consumer part before the hydraulic decoupling element (13). 6. Device according to any of claims 4 or 5, characterized in that the sensor devices (21, 21 ') are configured as temperature sensors. 7. Device according to claim 6, characterized in that with equal measurement data of the sensor devices (21, 21 '), the same value is set for the volumetric currents of the production circuit (11) and of the control circuit. consumption (12). Device according to any one of claims 2 to 7, characterized in that, instead of a single heat production device (14), several heat production devices (14, 14 ', 14''are provided) ) in the production circuit (11), and because the pump (17) is designed and sized so that the volumetric flow of the production circuit (11) passes, even through a single heat production device ( 14), it is sufficient to be able to generate a volumetric current that has the same value as that of the consumption circuit (12). Device according to any one of claims 2 to 7, characterized in that, instead of a single heat production device (14), several heat production devices (14, 14 ', 14''are provided) ) in the production circuit (11), and because the pump (17) is designed and dimensioned in such a way that the volumetric flow of the production circuit (11) passes, even through a single production device of heat (14), is sufficient to be able to generate a volumetric current that represents a fraction of the value of the volumetric current of the consumption circuit (12). 10. Device according to any of claims 2 to 7, characterized in that, instead of a single heat production device (14), several heat production devices (14, 14 ', 14''are provided) ) in the production circuit (11), and because the pump (17) is designed and dimensioned in such a way that the volumetric flow of the production circuit (11) passes, even through a single production device of heat (14), is sufficient to be able to generate a volumetric current that represents a multiple of the value of the volumetric current of the consumption circuit (12). Device according to any one of the preceding claims, characterized in that all the heat production devices (14, 14 ', 14'') of the production circuit (11) are driven by a pump (17, 17' , 17 '') common and adjustable. 12. Device according to any of the preceding claims, characterized in that each pump of heat production (14, 14 ', 14'') of the production circuit (11) is assigned a pump (17, 17' , 17 '') independent and adjustable. 13. Device according to any of the preceding claims, characterized in that each of the heat producing devices (14, 14 ', 14'') is assigned a volumetric current measuring device (24, 24 ', 24'') adjustable and independent. 14. Device according to any of the preceding claims, characterized in that the data signals measured by the volumetric current measuring device (24, 24 ', 24'') control a regulating device (34, 34 ', 34'') that regulates the volumetric current that passes through a heat producing device (14, 14', 14 ''). 15. Device according to claim 14, characterized in that the regulating device (34, 34 ', 34'') is configured in the form of a regulating valve. 16. Device according to claim 15, characterized in that the volumetric current measuring device (24, 24 ', 24'') is configured in the form of a differential pressure sensor that measures the difference in inlet pressure and output of a heat producing device (14, 14 ', 14''). 17. Device according to any of claims 1 to 16, characterized in that, as a decoupling element (13), a second conventional pipe system (16, 19) is provided, constructed at least with the secondary current flow in the direction to the primary current circulation, a part of the secondary current circulation being integrated into the primary current circulation. 18. Device according to any of claims 1 to 16, characterized in that the decoupling element (13) is formed in the form of a hydraulic decoupling device constituted by a hollow body having at least one inlet (26) and at least one outlet (27) to the piping system (16) of the production circuit (11) and at least one inlet (28) and at least one outlet (29) to the piping system (19) of the consumption circuit (12). 19. Device according to claim 18, characterized in that the decoupling element (13) is integrated in a second pipe system (19) constructed at least with the secondary current circulation towards the primary current circulation, the element of decoupling (13) being connected to a part of the secondary current circulation with the primary current circulation. 20. Device according to any of the preceding claims, characterized in that the sensor device (21, 21 ') is made in the form of an electronic sensor device that provides quantities in the form of electrical signals to the regulating device. 21. Device according to any of the preceding claims, characterized in that the activity of the pump (17, 17 ', 17'') provided in the production circuit (11) can be regulated continuously, to reduce and Increase pump power progressively. 22. Device according to claim 21, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is not established in relation to the producer but in relation to the volumetric current of the consumption circuit (12). 23. Device according to claim 22, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is established in such a way that the pump is capable of generate in the production circuit (11) a volumetric current that more or less corresponds to the volumetric current that circulates in the consumption circuit (12). 24. Device according to claim 22, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is established in such a way that it is capable of generating the production circuit (11) a volumetric current calculated at 105% of the volumetric current circulating in the consumption circuit (12). 25. Device according to claim 22, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is established in such a way that it is capable of generating the production circuit (11) a volumetric current calculated at 110% of the volumetric current circulating in the consumption circuit (12). 26. Device according to claim 22, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is established in such a way that it is capable of generating the production circuit (11) a volumetric current calculated at 115% of the volumetric current circulating in the consumption circuit (12). 27. Device according to claim 22, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is established in such a way that it is capable of generating the production circuit (11) a volumetric current calculated at 120% of the volumetric current circulating in the consumption circuit (12). 28. Device according to claim 22, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is established in such a way that it is capable of generating the production circuit (11) a volumetric current calculated at 90% of the volumetric current circulating in the consumption circuit (12). 29. Device according to claim 22, characterized in that the power of the pump (17, 17 ', 17'') provided in the production circuit (11) is established in such a way that it is capable of generating the production circuit (11) a volumetric current calculated at 95% of the volumetric current circulating in the consumption circuit (12). 30. Device according to any of the preceding claims, characterized in that the heat producing device (14, 14 ', 14''), which provides heat to the fluid (15), is configured in the form of an exchanger of heat 31. Device according to claim 30, characterized in that the heat exchanger is provided in the form of a plate heat exchanger. 32. Device according to claim 30, characterized in that the heat exchanger is provided in the form of a tubular beam heat exchanger. 33. Device according to claim 30, characterized in that the heat exchanger is provided in the form of a flue gas heat exchanger. 34. Device according to claim 30, characterized in that the heat exchanger is provided in the form of a collective heat exchanger.